DE102016211175A1 - Heating device for a tank, tank device for an exhaust aftertreatment system, exhaust aftertreatment system - Google Patents

Abstract

The invention relates to a heating device (3) for a tank (2), in particular an exhaust aftertreatment system, comprising a heating body (11) which is at least substantially enclosed by a housing (8) made of an electrically insulating material and electrically contactable by a drive device. It is provided that the heating element (11) is designed as a heating resistor and is assigned to a heat-conducting element, wherein the heat-conducting element extends through the housing as a closed heat-conducting wall (7).

Description

The invention relates to a heating device for a tank, in particular an exhaust aftertreatment system, with a radiator, which is at least substantially housed by a housing made of an electrically insulating material and electrically contacted by a drive means.

Furthermore, the invention relates to a tank device for an exhaust aftertreatment system of a motor vehicle, with a tank for receiving and providing a particular liquid exhaust aftertreatment agent and with a arranged in the tank / can be arranged heater.

Moreover, the invention relates to an exhaust aftertreatment system.

State of the art

Heating devices, tank facilities and exhaust aftertreatment systems of the type mentioned are known from the prior art. In order to meet the requirements of pollutant emissions in the exhaust gas of internal combustion engines in motor vehicles, it is known to post-treat the exhaust gas by means of appropriate exhaust aftertreatment systems. In addition to the use of one or more catalysts, a liquid exhaust aftertreatment agent is often injected into the exhaust gas, which reacts advantageously together with the exhaust gas in a downstream catalyst and selectively reduces pollutants in the exhaust gas. Widely used is the so-called SCR process (SCR = Selective Catalytic Reduction) in which an aqueous urea solution is injected as an exhaust aftertreatment agent into the exhaust gas upstream of an SCR catalyst so that in the catalyst the urea reacts with the exhaust gas and reduces nitrogen oxides in the exhaust gas.

Because known liquid exhaust aftertreatment agents can already freeze at temperatures just below 0 ° C, it is also known to provide a heater in a tank providing the exhaust aftertreatment means which heats and thaws frozen exhaust aftertreatment agent as needed. A known solution provides that the heating device comprises a stamped grid, which is encapsulated by a plastic and electrically contacted. By applying the punched grid with an electrical voltage heat is generated, which passes through the encapsulation in the tank and where appropriate heated frozen exhaust aftertreatment agent. Usually, the stamped grid extends as a body over the entire area to be heated and is traversed by current during operation accordingly. By providing varying cross-sections in the lead frame, active and passive heating ranges can be adjusted, with larger cross sections having a lower area performance than smaller cross sections, which means a higher electrical resistance to the current.

Disclosure of the invention

The heating device according to the invention with the features of claim 1 has the advantage that a homogeneous heat distribution is achieved by the heater, with passive heating areas are avoided. In addition, the temperature load on the housing is optimized due to the improved or homogenized heat distribution. Furthermore, the heater according to the invention is cheaper to produce and has a high level of ruggedness. According to the invention it is provided that the radiator is formed as a heating resistor and associated with a heat conducting element, wherein the heat conducting element extends through the housing as a closed heat conducting wall. The heat transfer through the housing is thus realized by the heat-conducting element and not by the radiator itself. The radiator is thereby smaller dimensioned in particular compared to the heat conducting element. The heat is thus generated locally by the radiator and advantageously distributed by the heat conducting element in the heater. Due to the fact that the heat-conducting element extends as a closed heat-conducting wall through the housing, a homogenized heat distribution in the housing is reliably ensured. In addition, can be dispensed with a complicated production of the stamped grid. The heat-conducting element is preferably made of aluminum or copper and therefore cost feasible. In addition, because the heat conducting wall is relatively stable and robust compared to a stamped grid, pre-injection molding of the stamped grid to stabilize it is eliminated during manufacture. This also further simplifies manufacturing and reduces costs.

According to a preferred development of the invention, it is provided that the housing is an encapsulation of the heat-conducting element. As a result, the housing is inexpensive and easy to produce. In addition, there is an advantageous heat transfer from the heat conducting element to the housing, since a contact with the contact of the heat conducting element is ensured to the housing over the entire surface.

Furthermore, it is preferably provided that the housing and the one heat-conducting element form a cylinder jacket wall in an annular manner. The heater thus receives a cylindrical shape whose shell wall of the housing and heat conducting element or Wärmeleitwand be formed. As a result, it is possible, in particular, to encompass a liquid removal point in the tank by the heating device in order, in particular, to ensure rapid and secure thawing of the frozen exhaust gas aftertreatment agent there.

Furthermore, it is preferably provided that the housing has a receiving pocket, in which the heating resistor is inserted. The heating resistor is thus not encapsulated by the housing, as the heat-conducting element, but subsequently plugged into the housing. As a result, a pre-assembly and, if necessary, a simple replacement of the heating resistor or radiator in a simple manner possible.

Preferably, the receiving pocket on a front side of the cylinder jacket wall has a receiving opening, through which the heating resistor can be inserted / inserted into the receiving pocket. Thus, the heating resistor or the radiator is axially inserted into the housing. This makes it possible that the heating resistor is located in a region of the housing, which is in particular not in contact with the exhaust aftertreatment agent in the tank. As a result, electrical connecting lines leading to the heating resistor can also pass through a region which is not in contact with the exhaust gas aftertreatment agent. In particular, the receiving opening during assembly in the tank of an opening of the tank is assigned such that through the opening and the receiving opening, the electrical lines can be placed, wherein the patch on the tank housing seals the opening and the receiving opening relative to the tank interior, so that the electrically conductive elements are safely separated from the exhaust aftertreatment agent.

According to a preferred embodiment of the invention, it is provided that the heating resistor is in touching contact with the heat conducting element. As a result, an advantageous heat transfer is ensured by the heating resistor in the heat conducting element. For this purpose, the heat-conducting element or the heat-conducting wall expediently extends through the receiving opening or forms an inner wall of the receiving opening, so that the heating resistor automatically comes into contact with the heat-conducting element when it is inserted into the receiving opening. Preferably, the receiving opening has a surface running obliquely with respect to the heat-conducting element, through which the heating resistor is forced against the heat-conducting element during insertion into the receiving pocket. As a result, when the heating resistor is inserted into the receiving opening, the contact with the heat-conducting element is produced in a simple manner and maintained during operation. The heating resistor is clamped or clamped between the housing and the heat-conducting element, so that a permanent contact with the contact is ensured.

Furthermore, it is preferably provided that at least one further functional element, in particular a temperature sensor, a filling level sensor and / or a conveying device is arranged on the housing. By means of the temperature sensor can be, for example, the temperature of the exhaust aftertreatment agent and thus determine the need for thawing or operation of the heater. By means of the level sensor, the level of the tank can be determined and by means of the conveyor, the exhaust gas aftertreatment agent can be removed from the tank. For this purpose, the conveying device in particular has a controllable pump whose suction connection is arranged in particular within the cylinder jacket wall, preferably centrally.

Furthermore, the housing preferably has means for attachment to the tank. The means may be, for example, screw openings, clamping means, screw means or plug means. As a result, a simple attachment of the housing to the tank or on a tank wall, in particular on a tank bottom, possible.

The tank device according to the invention with the features of claim 9 is characterized by the inventive design of the heater. This results in the already mentioned advantages.

The exhaust aftertreatment system according to the invention with the features of claim 10 is characterized by the tank device according to the invention. This also results in the already mentioned advantages.

Further advantages and preferred features and combinations of features emerge in particular from the previously described and from the claims.

In the following, the invention will be discussed with reference to the drawing. Show this

1 a sectional view of an advantageous tank means and

2 a perspective view of a heater of the tank device.

1 shows in a simplified sectional view of a tank device 1 with a tank 2 in which a heating device 3 is arranged. From the tank 2 is in the sectional view, only the tank bottom 4 shown. On the tank bottom 4 is the heater 3 on, which is formed substantially cylindrical.

2 shows the heater 3 in a perspective view. The heater 3 has a cylinder jacket wall 5 on, which extends annularly or forms a closed ring. A first front page 6 is the tank bottom 4 assigned.

The cylinder jacket wall 5 is essentially by a ring in the ring at least substantially continuous closed Wärmeleitwand 7 and a the Wärmeleitwand 7 surrounding housing 8th educated. The heat conducting wall 7 forms a heat-conducting element, that of the housing 8th is overmoulded. Preferably, the housing is made of HDPE (high density polyethylene). Because of the heat conduction wall 7 of the material of the housing 8th is overmolded, is a safe physical contact between housing 8th and heat conducting wall 7 ensures that an advantageous heat transfer can take place.

The housing 8th also has a storage bag 9 on, at the front 6 a receiving opening 10 having. Through the receiving opening is in the receiving pocket 9 axially a radiator 11 inserted, which is designed as an electrical heating resistor and by electrical lines 12 . 13 , in the 1 are shown by way of example, is electrically contacted. The wires 12 . 13 For example, lead to a control device or a control unit, which if necessary, the radiator 11 subjected to an electrical voltage, so that by the generated current flow and the corresponding resistance of the heating resistor or radiator 11 Heat is generated. The tank bottom 4 has the receiving opening 10 assigned a corresponding opening 14 on, through which the lines 12 . 13 can be led to the outside.

Through the receiving opening 9 also extends the Wärmeleitwand 7 through, leaving a side wall of the receiving opening 9 forms. The radiator 11 is directly on the heat conduction wall 7 arranged so that they are in contact with each other. Optional is between the radiator 11 and the heat-conducting wall 7 a viscous heat transfer agent 15 interposed, in particular production-related elevations or depressions in the material of the heat conducting wall 7 and / or the radiator 11 balances.

The receiving pocket is preferred 9 designed such that the radiator 11 between housing and Wärmeleitwand 7 is trapped to ensure a secure contact contact. Optionally, this can be done by the heat-conducting wall 7 opposite side wall of the receiving pocket 9 be aligned obliquely, as by a dashed line 16 indicated, so when plugging in the radiator 11 in the receiving bag 9 this against the Wärmeleitwand 7 is pressed.

The housing 8th is suitably with the tank bottom 4 screwed, glued and / or welded, so that the receiving pocket 9 only to the outside of the tank 2 is open or accessible. This ensures that the electrical components of the heater 3 safe in the tank 2 located exhaust aftertreatment agent are protected.

Because the heat conduction wall 7 closed by the housing 8th extends and with the radiator 11 is in contact, that of the radiator 11 generated heat in its control advantageous in the Wärmeleitwand 7 transfer, which distributes the heat in the tank interior evenly or homogeneously. This also causes a local temperature load on the housing 8th reduces and thus the durability of the heater 3 elevated. Due to the advantageous full-scale heat distribution, the power for warming up the frozen exhaust gas aftertreatment agent is reduced, especially at low levels or inclinations and the overall performance of the heater 3 increased over all levels. The heater 3 uses the available space in the tank 2 optimal and ensures optimized heat distribution over the entire circumference, a reduction in live areas, which for example benefits in terms of selection reliability or durability of the heater 3 offers. Because of the heat conduction wall 7 In particular, instead of a conventional stamped grid is used, costs and production costs are reduced. In particular, eliminates a pre-injection, which would be necessary to stabilize the stamped grid.

Due to the fact that live parts only in the receiving pocket 9 and from this through the receiving opening 10 and the opening 14 are led out, it is avoided that electrochemical interactions between different materials in the tank can take place. In particular, the housing 8th of the same material as the tank 2 manufactured, whereby also a welding of heating device 3 with tank 2 is relieved.

Claims (10)

Heating device ( 3 ) for a tank ( 2 ), in particular an exhaust aftertreatment system, with a radiator ( 11 ), of a housing ( 8th ) made of an electrically insulating material is at least substantially housed and electrically contacted by a drive device, characterized in that the radiator ( 11 ) is formed as a heating resistor and is associated with a heat conducting element, wherein the heat conducting element through the housing as a closed heat conducting wall ( 7 ). Heating device according to claim 1, characterized in that the housing ( 8th ) is an encapsulation of the Wärmeleitelements. Heating device according to one of the preceding claims, characterized in that the housing ( 8th ) and the heat-conducting element a cylinder jacket wall ( 5 ) extend annularly. Heating device according to one of the preceding claims, characterized in that the housing ( 8th ) a receiving bag ( 9 ), in which the heating resistor is inserted. Heating device according to one of the preceding claims, characterized in that the receiving pocket ( 9 ) on a front side ( 6 ) of the cylinder wall ( 5 ) a receiving opening ( 10 ), through which the heating resistor in the receiving pocket ( 9 ) can be used / used. Heating device according to one of the preceding claims, characterized in that the heating resistor is in touching contact with the heat conducting element. Heating device according to one of the preceding claims, characterized in that on the housing ( 8th ) at least one further functional element, in particular a temperature sensor, a level sensor and / or a conveyor is arranged. Heating device according to one of the preceding claims, characterized in that the housing ( 8th ) Means for attachment to the tank ( 2 ) having. Tank device ( 1 ) for an exhaust aftertreatment system of a motor vehicle, with a tank ( 2 ) for receiving and providing a particular liquid exhaust aftertreatment agent, and with a in the tank ( 2 ) arranged / arranged heater ( 3 ), characterized by the formation of the heating device ( 3 ) according to one or more of claims 1 to 8. Exhaust gas aftertreatment system with a tank device ( 1 ) according to claim 9.

Images